Abstract: Terahertz metamaterials comprise a periodic array of resonator elements disposed on a dielectric substrate or thin membrane, wherein the resonator elements have a structure that provides a tunable magnetic permeability or a tunable electric permittivity for incident electromagnetic radiation at a frequency greater than about 100 GHz and the periodic array has a lattice constant that is smaller than the wavelength of the incident electromagnetic radiation. Microfabricated metamaterials exhibit lower losses and can be assembled into three-dimensional structures that enable full coupling of incident electromagnetic terahertz radiation in two or three orthogonal directions. Furthermore, polarization sensitive and insensitive metamaterials at terahertz frequencies can enable new devices and applications.

Abstract: A multicolor photonic crystal laser array comprises pixels of monolithically grown gain sections each with a different emission centre wavelength. As an example, two-dimensional surface-emitting photonic crystal lasers comprising broad gain-bandwidth III-nitride multiple quantum well axial heterostructures were fabricated using a novel top-down nanowire fabrication method. Single-mode lasing was obtained in the blue-violet spectral region with 60 nm of tuning (or 16% of the nominal centre wavelength) that was determined purely by the photonic crystal geometry. This approach can be extended to cover the entire visible spectrum.

Abstract: A microfabricated particle focusing device comprises an acoustic portion to preconcentrate particles over large spatial dimensions into particle streams and a dielectrophoretic portion for finer particle focusing into single-file columns. The device can be used for high throughput assays for which it is necessary to isolate and investigate small bundles of particles and single particles.

Abstract: An optical switch includes a plurality of first optical fibers, a plurality of second optical fibers, a first MEMS array, and a second MEMS array. The first MEMS array is optically coupled with the first optical fibers to receive optical signals from the first optical fibers and to direct the optical signals, wherein the first MEMS array defines a first array incidence angle between a normal direction to the first MEMS array and a direction of the received optical signals. The second MEMS array is optically coupled with the first MEMS array to receive the directed optical signals and to re-direct the directed optical signals with the second optical fibers wherein the second MEMS array defines a second array incidence angle between a normal direction to second MEMS array and a direction of the re-directed optical signals. The configuration of the components is provided to provide reduced optical losses.

Abstract: An optical network element uses steerable mirrors in an optical switch to couple optical inputs and optical outputs. An optical switch has at least one array of the steerable mirrors, which can be oriented so as to reflect an optical signal between an input and an output. A shorter optical path between the input and the output reduces optical losses because optical losses in an optical switch using mirrors are directly proportional to the total length of the optical path. Reducing the optical path depends upon the switching tilt angle used in steering the mirrors. But tilting the micro-mirrors near their critical tilt angle or repeatedly across large tilt angles will degrade reliability or control. However, the total optical path can be shortened and the reliability of steerable mirrors can be maintained or increased if at least some of the micro-mirrors in an array are offset angled.

Abstract: An optical network element using steerable mirrors in an optical switch. A steerable mirror in the switch is connected to a potential bias having a magnitude greater than zero in order to reduce the operating potential of the integrated control system that steers the mirror.

Abstract: The position of a micro-mirror, for example, in an optical switch, may be monitored using an optical position control signals that are detected by a detector arrangement. The position of the micro-mirror may be adjusted by detecting the position of the beam spot and comparing the detected position to a desired position.

Abstract: An optical switch having a fiber/lens array and a switching substrate may be properly aligned using one or more static mirrors or photodetectors provided on the switching substrate. The static mirrors may be designed to reflect incident light back into an input fiber, where the back reflected light may be detected, or to a detector provided at a predetermined position. Accordingly, the position of the switching substrate and/or fiber/lens array may be adjusted until reflected light having predetermined power is detected. In another embodiment, the position of the switching substrate and/or fiber/lens array may be adjusted until predetermined power is detected by the photodetectors provided on the switching substrate.